# How to understand function recursion precisely?

I am currently programming some divide-conquer algorithms, where function recursions are used everywhere, but I have very vague idea or no idea how exactly it works, and that's why I post it here and hope you don't mind it's too basic.

For example, if we have the following code:

``````#include<iostream>
using namespace std;
void Recursion(int n)
{
cout << n << endl;
if(n > 0)
{
Recursion(n-1);
}
cout<<n<<endl;
}

int main()
{
Recursion(3);
return 0;
}
``````

I tested Recursion(3) and the print out in the terminal is:

``````3
2
1
0
0
1
2
3
``````

I can understand the concept of recursive call of the function but I don't understand the mechenism how it works. For example, what will they do after they can't call the function again? For example, here, I can understand it prints from 3 to 0 but why it also prints from 0 to 3 again? I heard it's because function recursion is stored in a stack for one recursion and when it reaches the "bottom" it also has to delete.

But anyway, I don't know about it. So, can anyone help me out and clearly tell me what happened here and the exact flow of function call?

-
Add a little distinction to your two output statements: cout << ">" << n << endl; ... cout << "<" << n << endl; Thus it will be made clear which line is printed by which statement. –  Andrey Chernyakhovskiy Jul 27 '13 at 22:41
@Andrey Good idea! –  Cancan Jul 27 '13 at 22:48
You would probably understand all code, not only recursive code, much better if you'd indent your code a bit. –  Ingo Jul 27 '13 at 22:48
Sorry, I indent very well in my laptop but I don't know how to format the code on stackoverflow properly, it seems I can only insert line by line. –  Cancan Jul 27 '13 at 22:52
@Cancan You can select code snippet in your editor, tab it 4 spaces and copy paste it into your question. –  greatwolf Jul 28 '13 at 0:00

The key to understanding recursion is the concept of the call stack. The call stack consists of "frames". A stack frame contains a function's local variables and an invisible return address. The classic physical analogy is a stack of plates. When you make a function call a plate (stack frame) is added to the top of the stack. When you return from a function the top plate (stack frame) is removed. You can only use the plate (stack frame) that is on top.

Recursive functions work the same way as ordinary functions. They are a little tricky because you can have multiple instances of their local variables on the stack at a given time. However, like other functions the function only refers to the stack frame that is on the top of the stack.

To illustrate how this works let's walk through your program showing how the call stack grows and shrinks.

Let's start with the base case: 0. `Recursion(0);`

1. Enter main: The stack is empty: Bottom of stack->||<-Top of stack
2. `Recursion(0);` Enter Recursion the stack has grown: Bottom of stack->|0|<-Top of stack
3. `cout << n << endl;` The value of n is 0 so the output is "0"
4. `if (n > 0)`. 0 is not greater than 0 so Recursion(-1) is not called.
5. `cout << n << endl;` The value of n is 0 so the output is "0"
6. Return to main() the stack is empty again: Bottom of stack->||<-Top of stack

The output would be

``````0
0
``````

Simple enough, no recursion took place. Let's take the next step. `Recursion(1);`

1. Enter main: Bottom of stack->||<-The top of stack
2. `Recursion(1);` Enter Recursion: Bottom of stack->|1|<-Top of stack
3. `cout << n << endl;` The value of n is 1 so the output is "1"
4. `if (n > 0)`. 1 is greater than 0 so `Recursion(0);` is called.
5. Enter Recursion: Bottom of stack->|1,0|<-Top of stack
6. `cout << n << endl;` The value of n in this stack frame is 0 so the output is "0"
7. `if (n > 0)`. 0 is not greater than 0 so the function does not recurse.
8. `cout << n << endl;` The value of n is 0 so the output is "0"
9. Return to the first call to Recursion. Bottom of stack->|1|<-Top of stack
10. `cout << n << endl;` The value of n is 1 so the output is "1"

Output

``````1
0
0
1
``````

Let's go through the execution one final time with n == 2

1. Enter main: Bottom->||<-Top
2. `Recursion(2);` Enter Recursion: Bottom->|2|<-Top
3. `cout << n << endl;` "2"
4. `if (n > 0)`. 2 is greater than 0 so `Recursion(1);` is called.
5. Enter Recursion: Bottom->|2,1|<-Top
6. `cout << n << endl;` "1"
7. `if (n > 0)`. 1 is greater than 0 so `Recursion(0);` is called.
8. Enter Recursion: Bottom->|2,1,0|<-Top
9. `cout << n << endl;` "0"
10. `if (n > 0)`. 0 is not greater than 0 so the function does not recurse again.
11. `cout << n << endl;` "0"
12. Return. Bottom->|2,1|<-Top
13. `cout << n << endl;` "1"
14. Return. Bottom->|2|<-Top
15. `cout << n << endl;` "2"

Output

``````2
1
0
0
1
2
``````
-

You are right, I also find recursive functions difficult to understand. Here is what i do, if i see a recursive function: run all the code step by step in your mind. This advice may seem trivial, but most of the time it works for me. Let's look at your code: You call Recursion() function with parameter 3. It prints n and n>0 that's why it calls Recursion(2) (note that we didn't return from the Recursion(3) call we are still in it and now we are also in Recursion(2). The same is for recursion(1) and 0. Now n>0 conditional is false. It prints 0. and we return from recursion(0) We print 1 and return from recursion(1) and it goes on the recursion(3)

``````Recursion(3)
Recursion(2)
Recursion(1)
Recursion(0)
return from Recursion(0)
return from Recursion(1)
return from Recursion(2)
return from Recursion(3)
``````
-
to clear this up you could add the `std::cout`s –  scones Jul 27 '13 at 22:47
Thanks, dude, you really told me what I want to know! –  Cancan Jul 27 '13 at 22:57

A function calling itself is not different from a function calling another function: before proceeding it has to wait that the function it has called returns.

By the way, recursion might look elegant, but in general it's not the most efficient way of programming: it makes for example impossible to inline functions, so the overhead for context switch is guaranteed. There's always a more efficient way to obtain the same result of a recursive function. But for some problems a recursive implementation is more intuitive, and not slower in any significant way. The example you gave in the comments, merge sort, is a good one.

Way to go from recursion to iteration
Can every recursion be converted into iteration?

My final advice: do not go for recursive when the problem does not require this approach, for example when computing a factorial.

-
But in some divide conquers problems, it seems it's impossible to avoid recursion such as merge sort and strassen algorithm for matrix multiplication –  Cancan Jul 27 '13 at 22:48
And, can I understand in this way? if I reach the bottom of the function call, e.g. Recursion(0) here, it will go back to Recursion(1) and execute the rest of the code in Recursion(1), since Recursion(1) calls Rersion(0). And by this logic, it generates the result. Do you think if this is correct? –  Cancan Jul 27 '13 at 22:51
Don't forget the MIT videos while studying CLRS book. :) They are also very valuable. I still remember most of the content of the book after graduation. –  Barış Akkurt Jul 27 '13 at 22:51
The remark regarding "efficiency" is an ill advice. Surely, Cancan is not in a position to think about micro-optimizations yet. It is more important to understand the code, and recursive problems lead most naturally to recursive algorithms. –  Ingo Jul 27 '13 at 22:51
@Ingo Thanks for your comment, I edited my answer. –  Antonio Jul 27 '13 at 23:12
show 1 more comment

Sometimes it is easier to understand recursion by starting at the base case, that is, the one that does not recurse. In your example, when n<=0, the call is resolved without more calls. Let's start by that.

If you call Recursion(0), the expected result is to print zero twice, one before and one after the if. The code inside the if does not execute.

Now, Recursion(1) does its first print of the value one, then calls Recursion(0) which in its turn prints 0 twice like before, then execution returns to Recursion(1), which prints 1 again, after the execution of Recursion(0). That is why you see 1 0 0 1. The same applies to Recursion(2), which will wrap the result of Recursion(1) around twos.

-